#!/usr/bin/env python
"""
Copyright 2006--2007-01-21 Paul Sladen
http://www.paul.sladen.org/projects/compression/

You may use and distribute this code under any DFSG-compatible
license (eg. BSD, GNU GPLv2).

Stand-alone pure-Python DEFLATE (gzip) and bzip2 decoder/decompressor.
This is probably most useful for research purposes/index building;  there
is certainly some room for improvement in the Huffman bit-matcher.

With the as-written implementation, there was a known bug in BWT
decoding to do with repeated strings.  This has been worked around;
see 'bwt_reverse()'.  Correct output is produced in all test cases
but ideally the problem would be found...
"""

import hashlib
import os
from collections import deque

import pyperf
import six
from six.moves import xrange


class BitfieldBase(object):

    def __init__(self, x):
        if isinstance(x, BitfieldBase):
            self.f = x.f
            self.bits = x.bits
            self.bitfield = x.bitfield
            self.count = x.bitfield
        else:
            self.f = x
            self.bits = 0
            self.bitfield = 0x0
            self.count = 0

    def _read(self, n):
        s = self.f.read(n)
        if not s:
            raise "Length Error"
        self.count += len(s)
        return s

    def needbits(self, n):
        while self.bits < n:
            self._more()

    def _mask(self, n):
        return (1 << n) - 1

    def toskip(self):
        return self.bits & 0x7

    def align(self):
        self.readbits(self.toskip())

    def dropbits(self, n=8):
        while n >= self.bits and n > 7:
            n -= self.bits
            self.bits = 0
            n -= len(self.f._read(n >> 3)) << 3
        if n:
            self.readbits(n)
        # No return value

    def dropbytes(self, n=1):
        self.dropbits(n << 3)

    def tell(self):
        return self.count - ((self.bits + 7) >> 3), 7 - ((self.bits - 1) & 0x7)

    def tellbits(self):
        bytes, bits = self.tell()
        return (bytes << 3) + bits


class Bitfield(BitfieldBase):

    def _more(self):
        c = self._read(1)
        self.bitfield += ord(c) << self.bits
        self.bits += 8

    def snoopbits(self, n=8):
        if n > self.bits:
            self.needbits(n)
        return self.bitfield & self._mask(n)

    def readbits(self, n=8):
        if n > self.bits:
            self.needbits(n)
        r = self.bitfield & self._mask(n)
        self.bits -= n
        self.bitfield >>= n
        return r


class RBitfield(BitfieldBase):

    def _more(self):
        c = self._read(1)
        self.bitfield <<= 8
        self.bitfield += ord(c)
        self.bits += 8

    def snoopbits(self, n=8):
        if n > self.bits:
            self.needbits(n)
        return (self.bitfield >> (self.bits - n)) & self._mask(n)

    def readbits(self, n=8):
        if n > self.bits:
            self.needbits(n)
        r = (self.bitfield >> (self.bits - n)) & self._mask(n)
        self.bits -= n
        self.bitfield &= ~(self._mask(n) << self.bits)
        return r


def printbits(v, n):
    o = ''
    for i in range(n):
        if v & 1:
            o = '1' + o
        else:
            o = '0' + o
        v >>= 1
    return o


class HuffmanLength(object):

    def __init__(self, code, bits=0):
        self.code = code
        self.bits = bits
        self.symbol = None
        self.reverse_symbol = None

    def __repr__(self):
        return repr((self.code, self.bits, self.symbol, self.reverse_symbol))

    @staticmethod
    def _sort_func(obj):
        return (obj.bits, obj.code)


def reverse_bits(v, n):
    a = 1 << 0
    b = 1 << (n - 1)
    z = 0
    for i in range(n - 1, -1, -2):
        z |= (v >> i) & a
        z |= (v << i) & b
        a <<= 1
        b >>= 1
    return z


def reverse_bytes(v, n):
    a = 0xff << 0
    b = 0xff << (n - 8)
    z = 0
    for i in range(n - 8, -8, -16):
        z |= (v >> i) & a
        z |= (v << i) & b
        a <<= 8
        b >>= 8
    return z


class HuffmanTable(object):

    def __init__(self, bootstrap):
        l = []
        start, bits = bootstrap[0]
        for finish, endbits in bootstrap[1:]:
            if bits:
                for code in range(start, finish):
                    l.append(HuffmanLength(code, bits))
            start, bits = finish, endbits
            if endbits == -1:
                break
        l.sort(key=HuffmanLength._sort_func)
        self.table = l

    def populate_huffman_symbols(self):
        bits, symbol = -1, -1
        for x in self.table:
            symbol += 1
            if x.bits != bits:
                symbol <<= (x.bits - bits)
                bits = x.bits
            x.symbol = symbol
            x.reverse_symbol = reverse_bits(symbol, bits)

    def tables_by_bits(self):
        d = {}
        for x in self.table:
            try:
                d[x.bits].append(x)
            except:   # noqa
                d[x.bits] = [x]

    def min_max_bits(self):
        self.min_bits, self.max_bits = 16, -1
        for x in self.table:
            if x.bits < self.min_bits:
                self.min_bits = x.bits
            if x.bits > self.max_bits:
                self.max_bits = x.bits

    def _find_symbol(self, bits, symbol, table):
        for h in table:
            if h.bits == bits and h.reverse_symbol == symbol:
                return h.code
        return -1

    def find_next_symbol(self, field, reversed=True):
        cached_length = -1
        cached = None
        for x in self.table:
            if cached_length != x.bits:
                cached = field.snoopbits(x.bits)
                cached_length = x.bits
            if (reversed and x.reverse_symbol == cached) or (not reversed and x.symbol == cached):
                field.readbits(x.bits)
                return x.code
        raise Exception("unfound symbol, even after end of table @%r"
                        % field.tell())

        for bits in range(self.min_bits, self.max_bits + 1):
            r = self._find_symbol(bits, field.snoopbits(bits), self.table)
            if 0 <= r:
                field.readbits(bits)
                return r
            elif bits == self.max_bits:
                raise "unfound symbol, even after max_bits"


class OrderedHuffmanTable(HuffmanTable):

    def __init__(self, lengths):
        l = len(lengths)
        z = list(zip(range(l), lengths)) + [(l, -1)]
        HuffmanTable.__init__(self, z)


def code_length_orders(i):
    return (16, 17, 18, 0, 8, 7, 9, 6, 10, 5, 11, 4, 12, 3,
            13, 2, 14, 1, 15)[i]


def distance_base(i):
    return (1, 2, 3, 4, 5, 7, 9, 13, 17, 25, 33, 49, 65, 97, 129, 193,
            257, 385, 513, 769, 1025, 1537, 2049, 3073, 4097, 6145, 8193,
            12289, 16385, 24577)[i]


def length_base(i):
    return (3, 4, 5, 6, 7, 8, 9, 10, 11, 13, 15, 17, 19, 23, 27, 31, 35,
            43, 51, 59, 67, 83, 99, 115, 131, 163, 195, 227, 258)[i - 257]


def extra_distance_bits(n):
    if 0 <= n <= 1:
        return 0
    elif 2 <= n <= 29:
        return (n >> 1) - 1
    else:
        raise "illegal distance code"


def extra_length_bits(n):
    if 257 <= n <= 260 or n == 285:
        return 0
    elif 261 <= n <= 284:
        return ((n - 257) >> 2) - 1
    else:
        raise "illegal length code"


def move_to_front(l, c):
    l.insert(0, l.pop(c))
    # EDB WAS
    #    l[:] = l[c:c + 1] + l[0:c] + l[c + 1:]


def bwt_transform(L):
    # Semi-inefficient way to get the character counts
    if six.PY3:
        F = bytes(sorted(L))
    else:
        F = b''.join(sorted(L))
    base = []
    for i in range(256):
        base.append(F.find(six.int2byte(i)))

    pointers = [-1] * len(L)
    for i, symbol in enumerate(six.iterbytes(L)):
        pointers[base[symbol]] = i
        base[symbol] += 1
    return pointers


def bwt_reverse(L, end):
    out = deque([])
    if len(L):
        T = bwt_transform(L)

        # STRAGENESS WARNING: There was a bug somewhere here in that
        # if the output of the BWT resolves to a perfect copy of N
        # identical strings (think exact multiples of 255 'X' here),
        # then a loop is formed.  When decoded, the output string would
        # be cut off after the first loop, typically '\0\0\0\0\xfb'.
        # The previous loop construct was:
        #
        #  next = T[end]
        #  while next != end:
        #      out += L[next]
        #      next = T[next]
        #  out += L[next]
        #
        # For the moment, I've instead replaced it with a check to see
        # if there has been enough output generated.  I didn't figured
        # out where the off-by-one-ism is yet---that actually produced
        # the cyclic loop.

        for i in xrange(len(L)):
            end = T[end]
            out.append(L[end])

    if six.PY3:
        return bytes(out)
    else:
        return b"".join(out)


def compute_used(b):
    huffman_used_map = b.readbits(16)
    map_mask = 1 << 15
    used = deque([])
    while map_mask > 0:
        if huffman_used_map & map_mask:
            huffman_used_bitmap = b.readbits(16)
            bit_mask = 1 << 15
            while bit_mask > 0:
                if huffman_used_bitmap & bit_mask:
                    pass
                used += [bool(huffman_used_bitmap & bit_mask)]
                bit_mask >>= 1
        else:
            used += [False] * 16
        map_mask >>= 1
    return used


def compute_selectors_list(b, huffman_groups):
    selectors_used = b.readbits(15)
    mtf = list(range(huffman_groups))
    selectors_list = deque([])
    for i in range(selectors_used):
        # zero-terminated bit runs (0..62) of MTF'ed huffman table
        c = 0
        while b.readbits(1):
            c += 1
            if c >= huffman_groups:
                raise "Bzip2 chosen selector greater than number of groups (max 6)"
        if c >= 0:
            mtf.insert(0, mtf.pop(c))
            # EDB WAS
            # move_to_front(mtf, c)
        selectors_list.append(mtf[0])
    return selectors_list


def compute_tables(b, huffman_groups, symbols_in_use):
    groups_lengths = deque([])
    for j in range(huffman_groups):
        length = b.readbits(5)
        lengths = []
        for i in range(symbols_in_use):
            if not 0 <= length <= 20:
                raise "Bzip2 Huffman length code outside range 0..20"
            while b.readbits(1):
                length -= (b.readbits(1) * 2) - 1
            lengths += [length]
        groups_lengths += [lengths]

    tables = deque([])
    for g in groups_lengths:
        codes = OrderedHuffmanTable(g)
        codes.populate_huffman_symbols()
        codes.min_max_bits()
        tables.append(codes)
    return tables


def decode_huffman_block(b, out):
    randomised = b.readbits(1)
    if randomised:
        raise "Bzip2 randomised support not implemented"
    pointer = b.readbits(24)
    used = compute_used(b)

    huffman_groups = b.readbits(3)
    if not 2 <= huffman_groups <= 6:
        raise Exception("Bzip2: Number of Huffman groups not in range 2..6")

    selectors_list = compute_selectors_list(b, huffman_groups)
    symbols_in_use = sum(used) + 2  # remember RUN[AB] RLE symbols
    tables = compute_tables(b, huffman_groups, symbols_in_use)

    favourites = [six.int2byte(i) for i, x in enumerate(used) if x]

    selector_pointer = 0
    decoded = 0
    # Main Huffman loop
    repeat = repeat_power = 0
    buffer = deque([])
    t = None
    while True:
        decoded -= 1
        if decoded <= 0:
            decoded = 50  # Huffman table re-evaluate/switch length
            if selector_pointer <= len(selectors_list):
                t = tables[selectors_list[selector_pointer]]
                selector_pointer += 1

        r = t.find_next_symbol(b, False)
        if 0 <= r <= 1:
            if repeat == 0:
                repeat_power = 1
            repeat += repeat_power << r
            repeat_power <<= 1
            continue
        elif repeat > 0:
            # Remember kids: If there is only one repeated
            # real symbol, it is encoded with *zero* Huffman
            # bits and not output... so buffer[-1] doesn't work.
            buffer.append(favourites[0] * repeat)
            repeat = 0
        if r == symbols_in_use - 1:
            break
        else:
            o = favourites[r - 1]
            favourites.insert(0, favourites.pop(r - 1))
            # EDB was
            # move_to_front(favourites, r - 1)
            buffer.append(o)
            pass

    nt = nearly_there = bwt_reverse(b"".join(buffer), pointer)
    i = 0
    # Pointless/irritating run-length encoding step
    while i < len(nearly_there):
        if i < len(nearly_there) - 4 and nt[i] == nt[i + 1] == nt[i + 2] == nt[i + 3]:
            out.append(nearly_there[i:i + 1] * (ord(nearly_there[i + 4:i + 5]) + 4))
            i += 5
        else:
            out.append(nearly_there[i:i + 1])
            i += 1

# Sixteen bits of magic have been removed by the time we start decoding


def bzip2_main(input):
    b = RBitfield(input)

    method = b.readbits(8)
    if method != ord('h'):
        raise Exception(
            "Unknown (not type 'h'uffman Bzip2) compression method")

    blocksize = b.readbits(8)
    if ord('1') <= blocksize <= ord('9'):
        blocksize = blocksize - ord('0')
    else:
        raise Exception("Unknown (not size '0'-'9') Bzip2 blocksize")

    out = deque([])
    while True:
        blocktype = b.readbits(48)
        b.readbits(32)   # crc
        if blocktype == 0x314159265359:  # (pi)
            decode_huffman_block(b, out)
        elif blocktype == 0x177245385090:  # sqrt(pi)
            b.align()
            break
        else:
            raise Exception("Illegal Bzip2 blocktype")
    return b''.join(out)


# Sixteen bits of magic have been removed by the time we start decoding
def gzip_main(field):
    b = Bitfield(field)
    method = b.readbits(8)
    if method != 8:
        raise Exception("Unknown (not type eight DEFLATE) compression method")

    # Use flags, drop modification time, extra flags and OS creator type.
    flags = b.readbits(8)
    b.readbits(32)   # mtime
    b.readbits(8)    # extra_flags
    b.readbits(8)    # os_type

    if flags & 0x04:  # structured GZ_FEXTRA miscellaneous data
        xlen = b.readbits(16)
        b.dropbytes(xlen)
    while flags & 0x08:  # original GZ_FNAME filename
        if not b.readbits(8):
            break
    while flags & 0x10:  # human readable GZ_FCOMMENT
        if not b.readbits(8):
            break
    if flags & 0x02:  # header-only GZ_FHCRC checksum
        b.readbits(16)

    out = deque([])
    while True:
        lastbit = b.readbits(1)
        blocktype = b.readbits(2)

        if blocktype == 0:
            b.align()
            length = b.readbits(16)
            if length & b.readbits(16):
                raise Exception("stored block lengths do not match each other")
            for i in range(length):
                out.append(six.int2byte(b.readbits(8)))

        elif blocktype == 1 or blocktype == 2:  # Huffman
            main_literals, main_distances = None, None

            if blocktype == 1:  # Static Huffman
                static_huffman_bootstrap = [
                    (0, 8), (144, 9), (256, 7), (280, 8), (288, -1)]
                static_huffman_lengths_bootstrap = [(0, 5), (32, -1)]
                main_literals = HuffmanTable(static_huffman_bootstrap)
                main_distances = HuffmanTable(static_huffman_lengths_bootstrap)

            elif blocktype == 2:  # Dynamic Huffman
                literals = b.readbits(5) + 257
                distances = b.readbits(5) + 1
                code_lengths_length = b.readbits(4) + 4

                l = [0] * 19
                for i in range(code_lengths_length):
                    l[code_length_orders(i)] = b.readbits(3)

                dynamic_codes = OrderedHuffmanTable(l)
                dynamic_codes.populate_huffman_symbols()
                dynamic_codes.min_max_bits()

                # Decode the code_lengths for both tables at once,
                # then split the list later

                code_lengths = []
                n = 0
                while n < (literals + distances):
                    r = dynamic_codes.find_next_symbol(b)
                    if 0 <= r <= 15:  # literal bitlength for this code
                        count = 1
                        what = r
                    elif r == 16:  # repeat last code
                        count = 3 + b.readbits(2)
                        # Is this supposed to default to '0' if in the zeroth
                        # position?
                        what = code_lengths[-1]
                    elif r == 17:  # repeat zero
                        count = 3 + b.readbits(3)
                        what = 0
                    elif r == 18:  # repeat zero lots
                        count = 11 + b.readbits(7)
                        what = 0
                    else:
                        raise Exception(
                            "next code length is outside of the range 0 <= r <= 18")
                    code_lengths += [what] * count
                    n += count

                main_literals = OrderedHuffmanTable(code_lengths[:literals])
                main_distances = OrderedHuffmanTable(code_lengths[literals:])

            # Common path for both Static and Dynamic Huffman decode now

            main_literals.populate_huffman_symbols()
            main_distances.populate_huffman_symbols()

            main_literals.min_max_bits()
            main_distances.min_max_bits()

            literal_count = 0
            while True:
                r = main_literals.find_next_symbol(b)
                if 0 <= r <= 255:
                    literal_count += 1
                    out.append(six.int2byte(r))
                elif r == 256:
                    if literal_count > 0:
                        literal_count = 0
                    break
                elif 257 <= r <= 285:  # dictionary lookup
                    if literal_count > 0:
                        literal_count = 0
                    length_extra = b.readbits(extra_length_bits(r))
                    length = length_base(r) + length_extra

                    r1 = main_distances.find_next_symbol(b)
                    if 0 <= r1 <= 29:
                        distance = distance_base(
                            r1) + b.readbits(extra_distance_bits(r1))
                        while length > distance:
                            out += out[-distance:]
                            length -= distance
                        if length == distance:
                            out += out[-distance:]
                        else:
                            out += out[-distance:length - distance]
                    elif 30 <= r1 <= 31:
                        raise Exception("illegal unused distance symbol "
                                        "in use @%r" % b.tell())
                elif 286 <= r <= 287:
                    raise Exception("illegal unused literal/length symbol "
                                    "in use @%r" % b.tell())
        elif blocktype == 3:
            raise Exception("illegal unused blocktype in use @%r" % b.tell())

        if lastbit:
            break

    b.align()
    b.readbits(32)   # crc
    b.readbits(32)   # final_length
    return "".join(out)


def bench_pyflake(loops, filename):
    input_fp = open(filename, 'rb')
    range_it = xrange(loops)
    t0 = pyperf.perf_counter()

    for _ in range_it:
        input_fp.seek(0)
        field = RBitfield(input_fp)

        magic = field.readbits(16)
        if magic == 0x1f8b:  # GZip
            out = gzip_main(field)
        elif magic == 0x425a:  # BZip2
            out = bzip2_main(field)
        else:
            raise Exception("Unknown file magic %x, not a gzip/bzip2 file"
                            % hex(magic))

    dt = pyperf.perf_counter() - t0
    input_fp.close()

    if hashlib.md5(out).hexdigest() != "afa004a630fe072901b1d9628b960974":
        raise Exception("MD5 checksum mismatch")

    return dt


if __name__ == '__main__':
    runner = pyperf.Runner()
    runner.metadata['description'] = "Pyflate benchmark"

    filename = os.path.join(#os.path.dirname(__file__),
                            "test", "original", "data", "interpreter.tar.bz2")
    bench_pyflake(1,filename)
#    runner.bench_time_func('pyflate', bench_pyflake, filename)
